Quarterly Journal of Optoelectronic

Current Issue

By Issue

By Author

By Subject

Author Index

Keyword Index

About Journal

Aims and Scope

Editorial Board

Publication Ethics

Indexing and Abstracting

Related Links

FAQ

Peer Review Process

Journal Metrics

News

Investigation of transmission modes in a binary disordered photonic crystal

Document Type : Research

Authors

null

Abstract

In this paper, the transmission spectrum of a disordered binary one dimensional photonic crystal with a defect layer is investigated in two states, the disordered of thickness and the disordered of optical path length in both polarizations TE and TM. Then the displacement of defect mode wavelengths is studied. As we observed the defect mode shifts toward the larger wavelength when the degree of disorder get increased in both symmetric and asymmetric cases. Furthermore, in a given degree of disorder the defect mode shifts toward the shorter wavelength as the incident angles get increased. These displacements are more tangible in TE polarization. In the symmetric structure the height of defect modes gets decreased by increasing the degree of disorder.

Keywords

References
 
[1] Saleh BE, Teich MC, Saleh BE. Fundamentals of photonics: Wiley New York; 1991.
[2] Skorobogatiy M, Yang J. Fundamentals of photonic crystal guiding: Cambridge University Press; 2009.
[3] Sukhoivanov IA, Guryev IV. Photonic crystals: physics and practical modeling: Springer; 2009.
[4] Gharaati A, Zare Z. Photonic band structures and enhancement of omnidirectional reflection bands by using a ternary 1D photonic crystal including left-handed materials. Progress In Electromagnetics Research. 2011;20:81-94.
[5] Zare Z, Gharaati A. Investigation of band gap width in ternary 1D photonic crystal with left-handed layer. Acta Physica Polonica A. 2014;125(1):36-8.
[6] Banerjee A. Enhanced refractometric optical sensing by using one-dimensional ternary photonic crystals. Progress in Electromagnetics Research. 2009; 89:11-22.
[7] Barati M, Aghajamali A. Near-infrared tunable narrow filter properties in a 1D photonic crystal containing semiconductor metamaterial photonic quantum-well defect. Physica E: Low-dimensional Systems and Nanostructures. 2016; 79:20-25.
[8] Chaves FS, Posada HV. Tuning of transmittance spectrum in a one-dimensional superconductor-semicon-ductor photonic crystal. Physica B: Condensed Matter. 2018; 543:7-13.
[9] Gharaati A, Zare Z. The effect of temperature on one-dimensional nanometallic photonic crystals with coupled defects. Pramana. 2017;88(5):75.
[10]Gharaati A, Azarshab H. Characterization of defect modes in one dimensional ternary metallo-dielectric nanolayered photonic crystal. Progress in Electromagnetics Research B. 2012; 371:25-141.
[11] Entezar S R. Photonic crystal wedge as a tunable multichannel filter. Superlattices and Microstructures. 2015; 82:33-39.
[12] Rao W, Song Y, Liu M, Jin C. All-optical switch based on photonic crystal microcavity with multi-resonant modes. Optik-International Journal for Light and Electron Optics. 2010;121 (21):1934-1936.
[13] Chen D, Vincent Tse M L, Tam H Y. Super-lattice structure photonic crystal fiber. Progress in Electromagnetics Research M. 2010; 11:53-64.
[14] Liu H, Tan C, Zhu C, Wang Y, Gao Y, Ma H, Cheng D. Simultaneous measurement of temperature and magnetic field based on directional resonance coupling in photonic crystal fibers. Optics Communications. 2017; 391: 111-115.
[15] Cox J, Singh M, Racknor C, Agarwal R. Switching in Polaritonic–Photonic Crystal Nanofibers Doped with Quantum Dots, Nano letters. 2011; 11(12): 5284-9.
[16] Fan Q, Li C, Liu W, Lu Y, Zhang D. Polarization-independent waveguides in air holes photonic crystals and its slow light. Optics Communications. 2016; 380: 227-232.
[17] Gersen H, Karle T, Engelen R, Bogaerts W, Korterik J, Van Hulst N, Krauss T, Kuipers L. Real-space observation of ultraslow light in photonic crystal waveguides. Physical review letters. 2005; 94 (7): 073903.
[18]Gharaati A, Zare Z. Modeling of thermal tunable multichannel filter using defective metallic photonic crystals. Optica Applicata. 2017;47(4):611-9.
[19]Wu C-J, Rau Y-N, Han W-H. Enhancement of photonic band gap in a disordered quarter-wave dielectric photonic crystal. Progress In Electro-magnetics Research. 2010; 100: 27-36.
[20]Yeh P. Optical waves in layered media: Wiley-Interscience; 2005.
 
Quarterly Journal of Optoelectronic
Volume 2, Issue 2 - Serial Number 6
June 2019
Pages 17-24
Files
Share
How to cite
Statistics